Transcript Slide 1

The Voltammetric Behaviour of Lead at a
Microband Screen-Printed Carbon Electrode
and its Determination in Acetate Leachates
from Glazed Ceramic Plates
Kevin C. Honeychurch and John P. Hart*
Centre for Research in Analytical, Material and Sensors Sciences, University of the West of England, Bristol, Coldharbour Lane, Frenchay, Bristol, BS16 1QY, UK.
* Corresponding Author: Tel. +44 117 3282469, Fax. +44 117 3282904, email [email protected]
Experimental
(a)
1
1.1
1.0
0.9
0.8
0.7
0.6
0
-1
0.5
0.4
0
5
10
15
20
25
30
35
Cl- , mM
-2
2.0
2.5
3.0
3.5
4.0
log accumulation time, s
Figure 4. Effect of Cl ions on the LSASV Peak current
for 0.1 M acetate buffer pH 4.1 solution containing
0.1 mM Pb. Voltammetric conditions: accumulation
time 60 s, accumulation potential -1.3 V.
Figure 5. Effect of accumulation time on the current
density gained at a microband SPCE and a 3x3 mm
SPCE for a 2.11 mg/l Pb solution in quiescence.
As can be seen from figure 5, much greater current densities can be gained from the µBSPCE
compared to the 3x3 mm SPCE under quiescent conditions. Pb stripping peaks were found to
increase linearly with time up to 1500 s (1.20 nA/s) becoming independent of time beyond this point.
Screen-printed
carbon tack
PVC
substrate
Dielectric
Macro working electrode (3x3 mm)
Ag/AgCl pseudoreference/counter
electrode
2
(a)
1.2
log current density, A/m2
Relatively high levels of Pb can be readily consumed as part of our diet from ceramic glazed
tableware containing Pb as part of the decorative pattern or glaze. Awareness of such problems
has generated a demand for methods that are rapid, inexpensive, reproducible, sensitive and
accurate. Electrochemical techniques such as anodic stripping voltammetry (ASV) offer a
number of advantages both in terms of economics, sensitivity, portability and easy of use,
requiring little more than an appropriate power supply for such applications.
Coupled to these advantages, the technique of ASV can also be tailored to give a wide dynamic
range from these extremely low levels to the ppm range, or higher.
However, previously, ASV has suffered from the common use of Hg working electrodes, the use
and subsequent disposal of which has lead to its lack of market penetration compared to other
techniques. However, there are a growing number of reports in which Hg-free SPCEs with
working electrodes in the micrometer (µm) range have been utilised, the radial diffusion inherent
with these devices allows for analysis to be made without the need for forced convection.
In this present study we have investigated the possibility of determining trace Pb concentrations
at a screen-printed microband electrode (µBSPCE). This to our knowledge is the first report on
the use of such microband electrodes for this application. In the first part of this study, we have
used cyclic voltammetry to optimise the voltammetric conditions necessary to determine Pb at
our µBSPCEs. In the second section, we then investigate the possibility of utilising these
electrodes using anodic stripping voltammetry (ASV) for the determination of Pb in the leachates
from glazed ceramic plates.
Effect of Chloride Ion Concentration
In order to explore the voltammetric behaviour and optimize the conditions for the ASV
determination of Pb at a microband SPCE, studies were made to ascertain the optimum
supporting electrolyte. For a 0.1 M pH 4.1 acetate buffer, it can be seen from Figure 4 that with
increasing NaCl concentration a notable increase the resulting ip for the Pb stripping peak is
obtained, with a maximum seen between 10 mM and 33 mM NaCl. Consequently, a 0.1 M pH
4.1 acetate buffer containing 13 mM NaCl was used in further investigations.
ip,µA
Introduction
(b)
Effect of Pb Concentration
Using an accumulation time of 1500 s in quiescence at an applied potential of 1.3 V (vs. Ag/AgCl),
a linear relationship with Pb concentration and ip was obtained from 50 µg/l to 1.70 mg/l (R2 =
0.999, 1.04 nA/ng/ml). Based on a signal-to-noise ratio of three a theoretical detection limit of 2.3
ng/ml was calculated. Using a shorter accumulation time of 15 s, a linear range of between 2 mg/l
and 50 mg/l Pb was obtained.
Interference Studies
Tin is often utilised in the form of stannic oxide in both glaze and as decoration. A peak at -0.473 V
was obtained for 38.7 mg/l Sn. However, this was found not interfere with the stripping peak gained
for Pb at a concentration of only 0.605 mg/l in the same solution (Figure 6).
100
Sn
Pb
Figure 6. The LSASV
determination of 0.605 mg/l Pb in
the presence of 38.67 mg/l Sn.
0
Microband working
electrode
Cut
i,nA
-100
-200
-300
Dielectric
(c)
-1.2
-1.0
-0.8
-0.6
-0.4
-0.2
0.0
E,V
Analytical Application
Microband working electrode
(2 mm x 20 µm)
Plate A
(b)
550
(a)
300
PVC substrate
200
A
16.84 µg/ml
500
12.63 µg/ml
450
8.42 µg/ml
400
100
4.21 µg/ml
350
sample
Results & Discussion
i,nA
-100
300
250
-200
200
-300
150
100
-400
50
-500
-1.2
-1.0
-0.8
-0.6
-0.4
-0.2
0.0
Plate B
0
-20
E,V
-10
0
10
20
Pb,µg/ml
550
500
(c)
1.0
B
450
400
350
0.5
ip,nA
300
i,µA
Voltammetric Conditions
Cyclic voltammograms were recorded in plain solutions (0.1 M) of the supporting electrolyte and then in the same solution
containing 0.1 mM of Pb. All solutions were purged with oxygen free nitrogen to eliminate oxygen reduction waves. The
voltammetric conditions were as follows: starting and finial potential, 0.0 V with a switching potential -1.7 V using a scan rate
50 mV/s. LSASV was carried out using a deposition time of either 15 s or 1500 s with an applied potential of -1.3 V (vs.
Ag/AgCl) in quiescence. All LSASV measurements were undertaken without prior purging with nitrogen. The measurement
step was undertaken using a starting potential of -1.3 V and an end potential of 0.0 V with a scan rate of 50 mV/s.
Sample Preparation
Two plates were selected as representative of the range that would be expected. Plate A, a highly decorated ornamental
plate, and plate B designed as tableware. Plates were first washed with deionised water and left to dry. An aliquot of 0.1 M
pH 4.1 acetate buffer was then pipetted onto the surface of the plate. This was then left for 24 h in the dark at room
temperature; covered to protect it from atmospheric deposition. The resulting solution was then transferred to a glass vial and
the volume adjusted to 20 ml. A 4 ml aliquot of this was then transferred to the voltammetric cell and the concentration of Pb
determined using the optimised LSASV conditions. The concentration of Pb present in the leachate was determined using the
method of multiple standard additions.
i,nA
0
Figure 1. Schematic diagram demonstrating the method for the manufacture of microband SPCEs from C10903P14. (a)
3x3 mm SPCE working electrode, with screen-printed Ag/AgCl pseudoreference/counter electrode. (b) Microband SPCE
(plan view). (c) Microband SPCE (cross section).
0.0
250
200
150
-0.5
100
50
-1.0
0
Cyclic voltammetric behaviour of Lead at Microband SPCEs
Figure 2 shows a typical cyclic voltammogram obtained for 0.1 mM Pb solution at our µSPCE.
Generally, the resulting voltammograms exhibited one cathodic peak on the forward negative going
scan and two sharp symmetrical anodic peaks on the return positive scan.
0.4
(a)
2.4
2.3
0.0
2.2
i,µA
Pb ip,µA
-0.2
-0.4
2.1
1.9
1.8
1.7
1.6
-1.0
-2.0
-1.5
-1.0
-0.5
0.0
E,V
Figure 2. Typical cyclic voltammograms obtained with a
microband SPCE for 0.1 M pH 4.1 acetate buffer/13 mM
NaCl, (a) in the absence of and (b) the presence of 0.1
mM Pb. Initial and final potentials: 0.0V; switching
potential -1.7 V; scan rate 50 mV/s .
-1.0
-0.8
-0.6
-0.4
-0.2
0.0
0
20
40
60
80 100 120
Pb, ng/ml
E,V
Figure 7. LSASVs of plate sample leachate at µBSPCEs (a) and (b) example voltammograms for added concentrations of Pb.
Accumulation time: 15 s for plate A and 1500 s for plate B, deposition potential -1.3 V (vs. Ag/AgCl) (b) and (d) resulting
standard addition plots.
Conclusions
2.0
-0.6
-0.8
-1.2
Figure 7a and 7b show a representative voltammograms obtained for the leachate from plates A and B,
with the corresponding standard addition plot shown in Figure 7b and 7d. The leachate from the
decorated ornamental plate A was found to contain a mean concentration of 20.01 mg/l Pb (%CV =
1.91 %). No detectable levels of Pb were found for plate B, however when fortified with 5.27 µg Pb, a
mean recovery of 82.1 % (%CV = 4.1 %) was recorded.
2.5
(b)
0.2
-100 -80 -60 -40 -20
1.5
-1.8
-1.6
-1.4
-1.2
-1.0
-0.8
E,V
Figure 3. Effect of deposition potential on the LSASVs for
a 0.1 mM Pb in 0.1 M pH 4.1 acetate buffer containing
13 mM NaCl at a microband SPCE. Accumulation time
60 s.
The effect of applied potential was studied for a 0.1 mM Pb solution over the range -0.7 V to -1.7 V
(vs. Ag/AgCl) using an accumulation time of 60 s (Figure 5). Under these conditions, the magnitude
of the stripping peak was found to increase with increasing negative potential, until forming a plateau
between -1.0 V and -1.6 V (vs. Ag/AgCl). Consequently, further investigations were made using an
applied potential of -1.3 V (vs. Ag/AgCl).
We have successfully demonstrated a relative quick and economic approach for the
manufacture of microband screen-printed carbon electrodes.
We have investigated the redox behaviour of Pb at these microband SPCEs prepared
from a commercial ink preparation (C10903P14) and found that well-defined anodic
peaks could be obtained in 0.1 M pH 4.1 acetate buffer containing 13 mM Cl using
LSASV.
It was shown that the magnitude of the anodic stripping peak for Pb was independent of
scan rate, indicative of steady state behaviour.
A simple and rapid method was developed for the determination of Pb by LSASV at a
Hg-free microband SPCE.
This is the first report on the use of such sensors for the determination of Pb in glaze
ceramic leachates.
Acknowledgements
The authors would like to thank the HEFCE for funding. They are grateful to Gwent Electronic
Materials Ltd. for supplying the screen-printed carbon electrodes. Saman Al-Berezanchi is thanked
for his assistance with preliminary studies.